Predicting multi-crystalline solar cell efficiency from life-time measured during cell fabrication

Many studies have been published on the use of minority-carrier lifetime testing at each step in a solar cell fabrication sequence. This paper illustrates one case of particular importance, multi-crystalline wafers with phosphorus diffusions. It is often stated that since the grains can have widely...

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Main Author: Sinton, R.A.
Format: Conference Proceeding
Language:English
Subjects:
Aging
Current density
Energy measurement
Fabrication
Life testing
Lifetime estimation
Photovoltaic cells
Semiconductor device modeling
Time measurement
Voltage measurement
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description Many studies have been published on the use of minority-carrier lifetime testing at each step in a solar cell fabrication sequence. This paper illustrates one case of particular importance, multi-crystalline wafers with phosphorus diffusions. It is often stated that since the grains can have widely disparate lifetimes, high-resolution lifetime mapping must be used with sophisticated analysis in order to predict the cell efficiency. This paper demonstrates that the simple Quasi-Steady-State area-averaged lifetime measurement method can give similar results to a more sophisticated analysis with high-resolution mapping data. The phosphorus diffusion can maintain a constant junction voltage during the measurement, effectively averaging the grain lifetimes in a manner mimicking the eventual solar cell in operation. The limitations for this result are described using a special case and a simplified model.
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This paper illustrates one case of particular importance, multi-crystalline wafers with phosphorus diffusions. It is often stated that since the grains can have widely disparate lifetimes, high-resolution lifetime mapping must be used with sophisticated analysis in order to predict the cell efficiency. This paper demonstrates that the simple Quasi-Steady-State area-averaged lifetime measurement method can give similar results to a more sophisticated analysis with high-resolution mapping data. The phosphorus diffusion can maintain a constant junction voltage during the measurement, effectively averaging the grain lifetimes in a manner mimicking the eventual solar cell in operation. 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identifier ISBN: 4990181603
ispartof 3rd World Conference onPhotovoltaic Energy Conversion, 2003. Proceedings of, 2003, Vol.2, p.1028-1031 Vol.2
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source IEEE Electronic Library (IEL) Conference Proceedings
subjects Aging
Current density
Energy measurement
Fabrication
Life testing
Lifetime estimation
Photovoltaic cells
Semiconductor device modeling
Time measurement
Voltage measurement
title Predicting multi-crystalline solar cell efficiency from life-time measured during cell fabrication
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